Note: Descriptions are shown in the official language in which they were submitted.
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Optical distributed sensor with Bragg grating sensing structure.
This invention relates to optical waveguide sensor
devices comprising two or more overlapped Bragg gratings.
Each grating has a phase shift, i.e. a longitudinal
discontinuity in the normally periodic structure of the
Bragg grating. The waveguide device may or may not be doped
with rare earth ions.
In optical fiber distributed sensor applications it is
a well known approach to multiplex several fiber Bragg
grating (FBG) sensors [1] along the same fiber. The center
frequency vBi of the main peak in the reflection spectrum of
an FBG, also known as the stop band, for light in
polarization i is given by:
c c
vBr=-_
ei,B, 2 n; A
v$i is also known as the center Bragg frequency and ~,Bi is the
Bragg wavelength. In equation (1), c is the speed of light,
ni, i=x,y is the generally polarization dependent refractive
index where x and y represents the two orthogonal polari-
zation states of the waveguide, and 11 is the periodicity of
the grating. Thus, a perturbation of ni or A by a measurand
will be detected as a shift of the Bragg frequency vBi. When
the FBG sensors are multiplexed, the localization of the
perturbation can be determined by using different periodici-
ty for each grating. Similar quasi-distributed sensing can
be achieved with Bragg grating based fiber lasers with rare
earth doped fiber.
An important characterizing parameter of the Bragg
grating in distributed sensor applications is the spatial
resolution. Bragg gratings can be made quite short, limited
by the UV beam size during the grating inscription. Alter-
natively, intra-grating perturbations of a Bragg structure
can be measured by simultaneously measuring the group delay
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and the power of the reflection spectrum [2]. However, when
using conventional FBGs, an increase in spatial resolution
invariably will lead to lower sensibility. Hence, there is a
demand for improved spatial resolution in such applications.
By introducing a phase shift in an otherwise uniform
Bragg grating, the two gratings at each side of the phase
shift will act as the mirrors of an optical resonator, and
there will be a narrow notch in the reflection spectrum of
the grating [3]. This notch may be referred to as the phase
shift notch, the center wavelength of which can be referred
to as the notch wavelength. If the phase shift equals ~ the
notch wavelength coincides with Bragg wavelength of a uni-
form Bragg grating.
As with ordinary Fabry-Perot cavities, we have no
reflection at the resonance if the mirror strengths of the
cavity are equal, meaning that the integrated coupling
strengths of the two grating halves are equal. The phase
shift notch is typically very narrow (less than one pm)
compared with the stop band of the grating, and it will have
a frequency splitting dv=vBB/n, where B=nx-ny is the
birefringence in the grating or fiber. If we have a uniform
physical perturbation across the grating, the phase shift
notch and Bragg wavelength will move in the same direction,
with both shifts controlled by equation (1). Thus because of
the narrowness of the phase shift notch, much smaller per-
turbations can be measured than for conventional FBGs. Since
different measurands perturb the birefringence to different
degrees, simultaneous measurements of two measurands can be
achieved by measuring the phase shift notches of both
polarizations.
By writing a FBG in a rare earth doped fiber, it is
possible to make distributed feedback lasers (DFB-FL).
Stable single longitudinal mode operation can be achieved by
adding a phase shift to the grating structure [4]. Single
polarization operation, if wanted, can be obtained for
instance by using polarization dependent gratings. The
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linewidth of the laser modes can be in the kHz range. An
advantage of DFB-FL sensors compared with the passive phase
shifted FBGs is that no complex opto-electronics is needed
to interrogate the sensor. Just like phase shifted FBGs,
dual polarization DFB-FLs can be used to simultaneously
measure two measurands [5].
For passive as well as active phase shifted FBG sen-
sors, it is important to note that the effective cavity
length is inversely proportional to the grating strength.
Thus, the sensor has an effective length that is far shorter
than the length of the grating [6].
FBGs with periodic superstructures are often called
sampled gratings or multiple wavelength fiber Bragg gratings
(MW-FBG). A simple sinusoidal sampling function corresponds
to a superposition of two uniform Bragg gratings with
different v$. The reflection spectra of such gratings will
have two reflection peaks slightly detuned from the stop
bands of the two superimposed Bragg gratings. By using more
complex sampling functions, or superimpose more gratings
with different periodicity A, gratings with several re-
flection peaks with similar shapes and widths can be achiev-
ed [7]. However, the maximum refractive index that can be
achieved in a fiber grating is limited by the photosensi-
tivity. Thus, the maximum achievable reflection strength
will decline with an increasing number of superimposed
uniform Bragg gratings.
Recently, dual wavelength DFB-FLs were reported, using
dual wavelength FBGs with a center phase shift [8]. It is
possible to make DFB-FL with more modes, but the maximum
number of modes is limited by the available photosensitivi-
ty of the fiber. We call such lasers for multiple wavelength
DFB-FLs (MW-DFB-FLs),
The objective of the invention is to provide fiber
optic quasi-distributed sensors with high spatial resolu-
tion, down to millimeters, and high resolution in the
measurand. The measurand may be any physical quantity that
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could change the effective index or length of the optical
fiber, for instance acoustic and static pressure, force,
temperature, or strain.
A second objective is to provide a sensor that measures
a gradient of the measurand.
A third objective is to be able to have simultaneously
quasi-distributed measurements of two measurands.
A fourth objective is to provide a fiber Bragg grating
that have an effective utilization of the available photo-
sensitivity of the optical fiber.
The objectives as set out above can be met by providing
an optical device for distributed sensing of a measurand
and/or changes thereof where the spectral transmission and
reflection characteristics of the device depend upon the
measurand. The device comprises a sensing section having at
least one Bragg grating sensing structure in a waveguide.
The Bragg grating sensing structure comprises at least two
superimposed or partly overlapping Bragg subgratings. The
Bragg sensing structure has at least two different peak
reflection wavelengths. At least two of the Bragg subgrat-
ings comprises a phase shift. The Bragg subgratings have
their phase shifts spatially separated from each other along
the waveguide sensing section.
The objectives can also be met by providing an optical
device as above with a sensing section at least partly doped
with rare earth ions which when pumped by a pump source, for
example a high-power semiconductor laser, provides lacing at
wavelengths determined by the gratings.
The objectives are also met by providing an optical
distributed sensor according to the invention for sensing an
external physical parameter wherein a tunable optical
narrowband optical source is providing light to one input
port of an optical waveguide coupling section. One output
port of the coupling section is coupled directly, or via a
waveguide lead section, to one end of an optical waveguide
sensing section. The other end of the sensing section is
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connected directly, or via another waveguide lead section,
to a first optical detection means 18 for allowing a measure
of light transmitted through the sensing section. A second
input port of the coupling section is coupled to a second
5 optical detection means for allowing a measure of light
reflected by the sensing section. The sensing section com-
prises at least one Bragg grating sensing structure in a
waveguide. The Bragg grating sensing structure has at least
two superimposed or partly overlapping Bragg subgratings.
The Bragg subgratings have at least two different peak
reflection wavelengths. At least one of the Bragg sub-
gratings comprises a phase shift, the phase shifts being
spatially separated from each other along the waveguide
sensing section.
The objectives can also be met by providing an optical
distributed sensor for sensing an external physical para-
meter according to the invention where an optical pump
source provides light to a first input port of a wavelength
division coupler/multiplexer. One port of the coupler/multi-
plexer is coupled directly, or via a waveguide lead section
section, to one end of an optical waveguide sensing section.
A second port of the optical coupler/multiplexer is connect-
ed to optical detection means for monitoring light from the
sensing section. The sensing section comprises at least two
Bragg grating sensing structure in a waveguide at least
partly doped with rare earth ions. The Bragg grating sensing
structure comprises at least two superimposed or partly
overlapping Bragg subgratings and has at least two different
peak wavelengths. At least one of the Bragg subgratings
comprises a phase shift, the phase shifts being spatially
separated from each other along the waveguide sensing
section.
If we have more than two subgratings, the phase between
the subgratings can be optimized for efficient use of the
available photosensitivity. For Ng subgratings with equal
strength x~, the maximum possible value of the total coupling
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function I tot I is N9K~. I tot I will be proportional to the
required photosensitivity. It can be shown that by optimiz-
ing the relative phase between the subgratings, the maximum
value of I xro~ I can be reduced from Nyx, to '~NgK;, ( for large
values of N9), because of cancellations between the different
Moire patterns. Note that it will not be possible to main-
tain this ideal phase relation everywhere in the MW-FBG/MW-
DFB-FL sensor structure since the subgrating phase shifts
are not co-located.
It is important to choose the right method of grating
fabrication in order to utilize the full potential of the
cancellations between the different Moire patterns. There
are two principal ways of fabricating MW-FBGs. Either the
MW-FBGs are produced by overlaying the subgratings one by
one, or they are fabricated by writing a grating with a
complex sampling function with an index profile equal to the
sum of the individual subgratings. In the latter method the
relative phases between the subgratings can be accurately
controlled. However, the maximum Bragg frequency spacing
between the subgratings with this method will be limited by
the spatial resolution (UV laser spot size) in the writing
setup. To obtain a large spacing the former method can be
used. However, in this case it may be difficult to control
the relative phases between the subgratings with sufficient
accuracy. Even if the relative phases are ideally optimized,
each subgrating will also contribute to a shift in the mean
refractive index that is independent of its phase, so the
lower limit to the needed refractive index contrast for the
MW-FBG corresponds to a grating of strength (Ng+_[(N9)])KS/2.
Thus, writing the subgratings one by one is a good idea if
the sensor application requires a large dynamic range or a
high linearity, which means that a large frequency spacing
between the subgrating is needed. However, if a large number
of subgratings, and thus efficient use of the photosensi-
tivity is most important, the MW-FBG grating structures
should be written in one scan using a complex sampling
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function.
Further preferred
embodiments
of the invention
are defined
in the subclaims.
The invention will be described in detail below with
reference to the accompanying drawings, illustrating the
invention by way of examples.
Fig. 1A shows an MW-FBG sensor consisting of four overlaid
subgratings with different pitch, having their
phase shift located at different positions.
Fig. 1B shows an MW-DFB-FL sensor operating at four
wavelengths, constructed by superimposing four
phase shifted subgratings, each having a phase
shift located at a different position.
Fig. 2A illustrates schematically the spatial distribution
of the resonant states of an MW-FBG or an
MW-FBG-FL sensor with the subgrating phase shift
positions separated together with the spatial
distribution of a measurand M.
Fig. 2B-C illustrates schematically the effect on the
different resonant frequencies induced by the
spatially varying measurand M.
Fig. 3 illustrates a superposition of three uniform phase
shifted FBGs with different periodicity, and
spatially separated phase shifts.
Fig. 4 illustrates a superposition of three phase shifted
FBGs with different periodicity, spatially
separated phase shifts, and amplitude and phase
of the superimposed gratings optimized for
efficient use of photo-sensitivity.
Fig. 5 illustrates an alternative superposition of three
phase shifted FBGs with different periodicity,
spatially separated phase shifts, and amplitude
and phase of the superimposed gratings optimized
for efficient use of the photo-sensitivity.
Fig. 6 shows a plot of the mode field distribution of a
MW-DFB-FL with grating structure as illustrated
in
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Figure 4 and a detuning betweeen the Bragg
frequencies of the superimposed gratings of 0v$=10
Ghz.
Fig. 7 shows the transmission spectrum of a MW-FBG of the
type illustrated in Figure 4 and with. w$=10 GHz.
Fig. 8A shows a plot of the detuning of the three modes
plotted in Figure 6 as a function of linear chirp,
Fig. 8B shows a plot of the beat frequencies between the
modes plotted in Figure 6 as a function of linear
chirp.
Fig. 9A shows plot of the detuning of the three modes
plotted in Figure 6 as a function of
quadratic chirp.
Fig. 9B shows a plot of the beat frequencies between the
modes plotted in Figure 6 as a function of the
quadratic chirp.
Fig. 10 shows a typical interrogation setup of a multiple
wavelength MW-DFB-FL sensor with the phase shifts
spatially separated using a tunable laser.
Fig. 11 shows a typical interrogation setup of a multiple
wavelength MW-DFB-FL sensor with the phase shifts
spatially separated.
Fig. 12A shows schematically serial multiplexing of MW-FBG
or MW-DFB-FL sensors.
Fig. 12B shows schematically parallel multiplexing of
MW-FBG-FL sensors.
Figure 1A shows, in a first preferred embodiment of the
invention, a multiple wavelength fiber Bragg grating (MW-
FBG) 1 with length Lg. The grating can be viewed as a super-
position of four uniform Bragg subgratings with different
Bragg frequencies, leading to a reflection R(v) and trans-
mission T(v) spectrum characterized by multiple transmission
stop bands, one per superimposed grating. Each subgrating
has a discrete or slightly distributed phase shift located
at the positions z~, z3, z4, and z5, respectively, leading to
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distinctive phase shift notches in each of the grating
reflective spectra.
Figure 1B shows, in a second preferred embodiment of
the invention, a grating similar to the one shown in Figure
1A with length Lg written in a rare earth doped optical fiber
of length Lf. Given a strong enough MW-FBG and enough gain,
such a device is called a multiple wavelength distributed
feedback laser (MW-DFB-FL) 6. The rare earth doped fiber is
in the preferred embodiment spliced to a conventional
optical fiber in one or both ends with connections 6 and 7.
If end pumped by sufficient power at the optical pump
wavelength ~, the grating structure will support multiple
lasing modes with frequencies v2, v3, v4, and v5. All laser
modes will generally emit optical power in both directions,
and the ratio between output powers in the left and right
directions will depend on the left and right end reflecti-
vity of the laser cavity of a given mode. If desirable, the
MW-DFB-FL can be made single polarization by using one of
several known techniques. The fiber laser can be pumped by
one or more pump sources, typically a semiconductor laser.
Although the Figures 1A and 1B shows a MW-FBG consist-
ing of four subgratings, it is of course possible to
fabricate MW-FBG and MW-DFB-FL with fewer as well as more
subgratings. A MW-FBG and a MW-DFB-FL can be fabricated
either by overlaying the subgratings one by one, or by
fabricating a grating with an index profile equal to the sum
of the individual subgratings.
In Figure 2A the power distributions Pi, i=2,..,5, for
incoming optical waves E(vi) to an MW-FBG like the one shown
in Figure 1A is plotted. The frequency vi of the wave is
equal to one of the phase shift notch frequencies of the
phase shifted MW-FBG. At each phase shift notch frequency,
there will be a resonance around the phase shift of the
corresponding subgrating. The power will fall off sharply in
a close to exponential manner as a function of the product
of distance from this phase shift and the subgrating
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strength. The modes of a MW-DFB-FL as shown in Figure 1B,
will have a similar modal spatial power distribution. Figure
2A also shows a plot of an example of the spatial distri-
bution of a measurand M along the fiber axis. The measurand
5 can for instance be temperature, strain, static or acoustic
pressure, force, or any other physical property that can
perturb the effective refractive index, nX or ny, periodicity
!1 of the grating structure, or the birefringence B=nn-ny of
the fiber.
10 Figure ~B-C schematically shows the effect of the
perturbations caused by a varying measurand M as plotted in
Figure 2A on the different laser modes or phase shift notch
frequencies of the structures shown in Figure 1A or 1B.
Figure 2B shows the case of no external influence, i.e. M=0.
Figure 2C shows the effect of an external influence, i.e.
MAO. Because of the confinement of the power at the
resonances, each laser mode or phase shift notch frequency
depend mainly on the grating structure in near proximity to
the corresponding subgrating phase shifts, and perturbations
further away will have little effect. For pedagogic reasons,
it has been assumed that the phase shift notch or laser
frequency vi and the position of the phase shifts zi of each
subgrating is ordered in the same way, but this is not
necessary for the operation of the invention. Around z~ and
z3 M is positive, resulting in a positive shift Sv2 and 8v3,
respectively, of the corresponding resonance frequencies v2
and v3. Around z4 and z5, M is negative, resulting in a
negative frequency shift w4 and w5 of the corresponding
resonance frequencies v4 and v5, respectively. The sign of
the ratio M/8vi is here set arbitrarily and could be oppo-
site for some measurands. Because of the perturbation, the
beat frequency betweeen the resonance around phase shift i
and phase shift j becomes:
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d~,t~=Ova+~y~-~vt=y°-y°+~~~-~y~ i,j=2,,,5
0
Here v' is the resonance frequency of the phase shift i
before the onset of the perturbation caused by M.
The ratio of change in birefringence to change in Bragg
gxating frequency depends on the type of measurand. Thus, it
is, in some cases, possible to separate two measurands by
simultaneously measuring the polarization splitting and
frequency shift of the MW-FBG shown in Figure 1A. Likewise,
a dual measurand sensor can be made by measuring all fre-
quencies or beat frequencies of a M~nT-DFB-FL as shown in
Figure 1B where all subgratings support lasing modes in both
polarizations. Since this technique is known for conven-
tional phase shifted gratings and DFB-FLs [6], it will not
be described in any further detail here.
There axe in principle an infinite number of ways of
designing this invention, and in Figures 3-5 a few illu-
strating examples axe given.
Figure 3 illustrates a superposition of three uniform
subgratings with equal coupling coefficients K1=~cz=x3, all
having a phase shift 9 of ~t in the middle. The subgratings,
including their phase shifts 9, are spatially shifted from
each other, leading to a grating structure similar to the
ones shown in Figures 1A-1B. The subgratings are only
partially overlapping, and the phase relation between the
subgratings changes at each subgrating phase shift 9. This
results in total coupling efficiency IKtot) that varies
significantly along the grating axis. IK~otl is proportional
to the required refractive index contrast.
In Figure 4 another MW-FBG with three phase shifted
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subgratings is illustrated. The distance between the ~t phase
shifts 9 of the different subgratings is the same as in
Figure 3, but each subgrating amplitude is varying along the
fiber axis in such a way that the total required refractive
index contrast is constant. At the same time, the reflec-
tivity of each subcavity mirror was kept equal. This leads
to a much shorter device length for a given grating
reflectivity level than the one illustrated in Figure 3, or
for a given length a lower maximum index modulation.
Furthermore, in order to increase the spatial resolution of
the sensor, the resonant mode field distribution should be
spatially separated as much as possible, and therefore the
phase between the gratings are optimized in the region
between the phase shifts.
The third example shown in Figure 5 is also a structure
consisting of three superimposed phase shifted Bragg grat-
ings, with the same phase shift separation as in Figures 3-
4, Here the subgratings are not overlapping between the
phase shifts 9. Instead, the spatial resonance separation is
enhanced by assigning each subgrating all available index
contrast around its phase shift. The structure has similari-
ty with the one shown in Figure 4, in that the required
refractive index contrast everywhere is the same, and in
that the inter-grating phase is optimized at the edges of
the grating.
Figure 5 shows the calculated modal field distributions
of a MW-DFB-FL of the design type illustrated in Figure 6.
The separation between each phase shift is 2.5 cm, the
grating length is 12.3 cm, the maximum grating strength is
I~totl=200 m 1, and the difference in Bragg frequency between
the different subgratings is w=10 GHz. These parameters are
typical for a real grating. The power difference between the
most powerful and next most powerful modes at the phase
shifts are 20 dB at the center phase shift and 22 dB at the
outer phase shifts. The spatial power distribution of the
field at the different spectral phase shift notches with a
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passive grating will be similar.
Regardless of the principle chosen for the super-
position of the subgratings, the fiber photosensitivity will
be the limiting factor of the spatial resolution, With
higher number of measurement points, the available photo-
sensitivity has to be shared between more subgratings,
leading to less confined resonance cavities and larger
spatial overlap between the modes, and at some point the
spatial resolution will not increase by increasing the
number of gratings. For DFB-FL devices, each grating has to
be strong enough to support a laser mode, which could limit
the obtainable density of measurement points further. For
passive, phase-shifted structures, weaker gratings means
reduced resolution of the measurand.
For easy fabrication and interrogation of the
invention, it is desirable to have the Bragg frequencies
spaced as densely as possible. However, in order to avoid
nonlinearities in the response, the stopbands and strongest
sidebands of the different subgratings should not overlap.
The smallest possible Bragg frequency separation between the
subgratings is thus dependent on the coupling strength and
linearity specifications.
In Figure 7, the calculated transmission spectrum of
the grating structure discussed in the previous paragraph
without gain is plotted. Although there is some overlap
between the sidebands, the three stopbands in the spectrum
are clearly separated. The phase shift notch, which in the
transmission spetrum in Figure 7 appears as sharp peaks, are
too narrow to be completely resolved by the simulations. In
Figures 8A-B,9A-B the effect of linear and quadratic chirp,
respectively, in the structure is shown. In Figures 8A,9A
the detuning from the 10 GHz Bragg frequency spacing of the
subgratings are plotted, whereas in Figures 8B,9B the beat
frequencies between the spatial middle mode and the left and
right mode are plotted. In the linear chirp case, these two
beat frequencies are equal to each other because of the
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symmetry of the device. The response is reasonably linear
with a linear chirp ranging from -20 to 20 GHz/m and a
quadratic chirp between -550 GHz/m2 and 550 GHz/m2. The range
in the linear chirp case corresponds to a temperature
gradient range of approximately ~17°C/m or strain gradient
range of ~194 ~s/m. The range in the quadratic chirp case
corresponds to a second order Taylor coefficient of
approximately ~470°C/m~ in temperature and ~5.3 ms/m2 in
strain.
Figure 10 shows an embodiment of the invention where
remote interrogation of a passive phase shifted MW-FBG
sensor 1 with a tunable laser 16 is shown. The laser should
scan over the phase shift notches of the MW-FBG 1 and either
the reflected 17 or transmitted 18 light should be measured.
By synchronizing the detector with the laser, the frequenc-
ies of the phase shift notches can be found. The tunable
laser should have a narrow linewidth and in some cases it
may be advantageous to monitor its output frequency to
ensure accurate measurements, for example using a spectro-
meter. For higher resolution in time or measurand, it may in
some applications be necessary to have several tunable
lasers multiplexed at the source end of the system, with
filters in the receiving end distributing the different
frequencies to separate detectors.
Figure 11 shows an embodiment of the invention where a
typical interrogation setup of a MW-DFB-FL sensor is shown.
From the pump source 19, which typically is a semiconductor
laser, the pump light is guided through a wavelength
division multiplexer (WDM) 20 and lead fiber 12 to the MW-
DFB-FL 6. The laser light emitted from the pump side of the
MW-DFB-FL 6 will be led back through the lead fiber 12 and
to the signal arm of the WDM 20 for monitoring of the laser
mode frequencies 22. To avoid back-reflection into the laser
cavity an optical isolator 21 can be used. Alternatively,
the MW-DFB-FL laser can be monitored from the right end of
the MW-DFB-FL. Also when monitoring the various laser
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frequencies many techniques could be employed. Each laser
frequency can be tracked independently by using an array of
filters. Alternatively, beat frequencies between the modes
can be measured with lower demands on filters but perhaps
5 with increased requirements on fast electronics. For
gradient sensors, the beat frequencies only are of interest,
thus normally fast electronics. For other applications, the
average state of the MW-DFB-FL sensor is of interest. In
this case at least one of the MW-DFB-FL modal frequencies
l0 has to be determined.
Figures 12A and 12B show embodiments of the invention
including serial and parallel multiplexing of the sensors.
Such multiplexing will be useful for instance in distributed
gradient measurements. In both fundamental ways of multi-
15 plexing, the gratings can be interrogated with the same
optoelectronic units 23 and 24, i.e. the different MW-FBG 1
or MW-DFB-Fh 6 sensors can share the same interrogating or
pump sources, respectively, and receiving optoelectronics.
In Figure 12B, the light from the interrogating or pump
sources is guided through a lead fiber to a coupler 25 or
array of couplers that distribute the source light to the
passive 1 or active 6 MW-FBG sensors. In the case where the
sensor is interrogated at the output side, another coupler
is required to collect the signals from the various
25 sensors in a common opto-electronic unit.
Other types of mulitplexing arrangement for example
involving a combination of parallel and serial multiplexing
are possible.
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